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Diamond Single Photon Source. This project will enhance Australia's international profile in the area of quantum technology and will link, for the first time, diamond single photon capability with fibre optics technology, building on the strengths of both fields. The innovative steps in photonics and materials science which we are initiating place us in a unique position to exploit the emerging niche market for single photon sources. A provisional patent application for this technology is bein ....Diamond Single Photon Source. This project will enhance Australia's international profile in the area of quantum technology and will link, for the first time, diamond single photon capability with fibre optics technology, building on the strengths of both fields. The innovative steps in photonics and materials science which we are initiating place us in a unique position to exploit the emerging niche market for single photon sources. A provisional patent application for this technology is being lodged by the applicant and University of Melbourne colleagues in conjunction with QUCOR Pty Ltd. Success in researching and developing this device will help consolidate Australia's reputation as a global contributor to leading edge science and technology. Read moreRead less
Defect-induced luminescence from ion-implanted silicon: Towards silicon photonics applications. This project focusses on advanced materials science, photonics and innovative silicon optical devices that have potential for contributing to information and communications technologies, areas where Australia has considerable expertise and investment. Specifically, national benefit will be derived from breakthroughs in fundamental science and intellectual property.
Diamond Based Quantum Information Processing. The explosive growth in ideas for applications of quantum mechanics to practical devices for information processing has been a worldwide phenomenon of the past 4 years. A leading material which promises many of the desirable quantum properties is diamond. We aim to build on our extensive expertise in fundamental diamond research to design, fabricate and analyse novel quantum devices made from diamond. We will seek to attain the glittering prize of ....Diamond Based Quantum Information Processing. The explosive growth in ideas for applications of quantum mechanics to practical devices for information processing has been a worldwide phenomenon of the past 4 years. A leading material which promises many of the desirable quantum properties is diamond. We aim to build on our extensive expertise in fundamental diamond research to design, fabricate and analyse novel quantum devices made from diamond. We will seek to attain the glittering prize of constructing diamond devices that will absorb, store and re-emit single light-photons with revolutionary applications to information storage and processing.Read moreRead less
Diamond Based Quantum Information Processing. The explosive growth in ideas for applications of quantum mechanics to practical devices for information processing has been a worldwide phenomenon of the past 4 years. A leading material which promises many of the desirable quantum properties is diamond. In collaboration with our Israeli colleagues we will seek to attain the glittering prize of constructing diamond devices that will absorb, store and re-emit single light-photons with revolutionary ....Diamond Based Quantum Information Processing. The explosive growth in ideas for applications of quantum mechanics to practical devices for information processing has been a worldwide phenomenon of the past 4 years. A leading material which promises many of the desirable quantum properties is diamond. In collaboration with our Israeli colleagues we will seek to attain the glittering prize of constructing diamond devices that will absorb, store and re-emit single light-photons with revolutionary applications to information storage and processing.Read moreRead less
Functional micro-multiplexers based on nonlinear three-dimensional photonic crystal superprisms. The development of functional nonlinear micro-multiplexers is vital to on-chip applications in optical information processing, telecom and bio-sensing. The proposed project will enable both enormous improvements of device performance and the significant reduction in the cost and size of the associated infrastructures and eventually facilitate the next generation miniaturised all-optical networks. The ....Functional micro-multiplexers based on nonlinear three-dimensional photonic crystal superprisms. The development of functional nonlinear micro-multiplexers is vital to on-chip applications in optical information processing, telecom and bio-sensing. The proposed project will enable both enormous improvements of device performance and the significant reduction in the cost and size of the associated infrastructures and eventually facilitate the next generation miniaturised all-optical networks. The success of the project will make essential contributions to the emerging photonics and nanotechnology, and strengthen Australia's international leading role in these fields. The improvement of device performance, the development of new IP, and the commercialisation of novel products will deliver major social and economic benefits to Australia.Read moreRead less
New generation of hyperspectral infrared photon detectors. Although highly desirable for many applications, tuneable, on chip, infrared photon detectors are not yet available. The approach described in this application aims to develop a technology for high performance, on chip, infrared photon detectors that can be tuned over a wide wavelength range. By applying a novel in-house developed semiconductor process and a multi-disciplinary approach, this project aims to develop such devices by combin ....New generation of hyperspectral infrared photon detectors. Although highly desirable for many applications, tuneable, on chip, infrared photon detectors are not yet available. The approach described in this application aims to develop a technology for high performance, on chip, infrared photon detectors that can be tuned over a wide wavelength range. By applying a novel in-house developed semiconductor process and a multi-disciplinary approach, this project aims to develop such devices by combining, for the first time, micromachined tuneable optical microcavities with high performance HgCdTe-based infrared detectors.Read moreRead less
Electronic properties of diamondlike carbon for applications in planar optical waveguides. This project will explore new applications of diamondlike carbon in the area of integrated optics for telecommunications systems. Diamondlike carbon offers opportunities to create novel electro-optic devices owing to its high refractive index and its ability to be deposited directly onto silicon substrates. This project will conduct a thorough study of the electronic properties of diamondlike carbon depo ....Electronic properties of diamondlike carbon for applications in planar optical waveguides. This project will explore new applications of diamondlike carbon in the area of integrated optics for telecommunications systems. Diamondlike carbon offers opportunities to create novel electro-optic devices owing to its high refractive index and its ability to be deposited directly onto silicon substrates. This project will conduct a thorough study of the electronic properties of diamondlike carbon deposited by two techniques and develop potential niche applications in the $5 billion integrated optical telecommunications devices. The work will combine fundamental studies of thin film electronic properties with leading edge industry applications of technology and provide an excellent research training opportunity.Read moreRead less
Infrared optoelectronic sensors based on p-type molecular beam epitaxy grown HgCdTe. The ability of infrared detectors to directly sense the thermal output of an object has applications in medicine, search and rescue, bushfire detection and in the defence and surveillance industries. The highest performing infrared detectors are photon detectors based molecular beam epitaxy (MBE) grown HgCdTe. The primary aims of this project relate to the fundamental understanding of p-type doping in MBE grown ....Infrared optoelectronic sensors based on p-type molecular beam epitaxy grown HgCdTe. The ability of infrared detectors to directly sense the thermal output of an object has applications in medicine, search and rescue, bushfire detection and in the defence and surveillance industries. The highest performing infrared detectors are photon detectors based molecular beam epitaxy (MBE) grown HgCdTe. The primary aims of this project relate to the fundamental understanding of p-type doping in MBE grown HgCdTe, a current and major difficulty in HgCdTe technology, and the use of such p-type MBE grown layers in conjunction with a newly developed plasma process based n-p junction formation technology to realise novel and innovative infrared detector structures. Such structures would have the ability to revolutionise the use of HgCdTe in infrared detectors and focal plane array applications.Read moreRead less
Design and Experimental Demonstration of Ultrabroadband Silicon Optical Amplifiers. The current success of the electronics industry rests on pillars made from the low cost, high performance and flexibility of silicon compounds. Silicon-based optics provides a new platform for the monolithic integration of optics and electronics. In this project, a multi-disciplinary team consisting of pioneers of nonlinear optics and siliconized photonics build a next-generation broadband silicon optical amplif ....Design and Experimental Demonstration of Ultrabroadband Silicon Optical Amplifiers. The current success of the electronics industry rests on pillars made from the low cost, high performance and flexibility of silicon compounds. Silicon-based optics provides a new platform for the monolithic integration of optics and electronics. In this project, a multi-disciplinary team consisting of pioneers of nonlinear optics and siliconized photonics build a next-generation broadband silicon optical amplifier which can open the door to a new low-power, wide-bandwidth, high-speed and ultra-small optoelectronic devices. The technological advances arising from this project will provide Australia with critical capabilities for future commercial ventures and strengthen Australia's stake in the multi-trillion dollar semiconductor industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883038
Funder
Australian Research Council
Funding Amount
$160,000.00
Summary
Upgrade key fabrication equipment for specialty fibre and device research and development. Australia remains a world leader in enabling technologies spanning information and communication, lasers, photonic sensing and diagnostics and much more. Underpinning much of this have been key backbone facilities at UNSW and at Sydney. Optical fibre research internationally is moving in new directions and for Australia to continue its leadership role, dedicated facilities for new generation structured opt ....Upgrade key fabrication equipment for specialty fibre and device research and development. Australia remains a world leader in enabling technologies spanning information and communication, lasers, photonic sensing and diagnostics and much more. Underpinning much of this have been key backbone facilities at UNSW and at Sydney. Optical fibre research internationally is moving in new directions and for Australia to continue its leadership role, dedicated facilities for new generation structured optical fibres, which are already impacting much more significantly than conventional fibres, must be available. The upgrade at UNSW will position Australia to continue its leadership and introduce educational and vocational training for the new industries that will depend on these core technologies. Read moreRead less